The different ideal #
Main definition #
Submodule.traceDual
: The dualL
-subB
-module under the trace form.FractionalIdeal.dual
: The dual fractional ideal under the trace form.differentIdeal
: The different ideal of an extension of integral domains.
Main results #
conductor_mul_differentIdeal
: IfL = K[x]
, withx
integral overA
, then𝔣 * 𝔇 = (f'(x))
withf
being the minimal polynomial ofx
.aeval_derivative_mem_differentIdeal
: IfL = K[x]
, withx
integral overA
, thenf'(x) ∈ 𝔇
withf
being the minimal polynomial ofx
.
TODO #
- Show properties of the different ideal
noncomputable def
Submodule.traceDual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
(I : Submodule B L)
:
Submodule B L
Under the AKLB setting, Iᵛ := traceDual A K (I : Submodule B L)
is the
Submodule B L
such that x ∈ Iᵛ ↔ ∀ y ∈ I, Tr(x, y) ∈ A
Equations
- Submodule.traceDual A K I = let __spread.0 := (Algebra.traceForm K L).dualSubmodule (Submodule.restrictScalars A I); { toAddSubmonoid := __spread.0.toAddSubmonoid, smul_mem' := ⋯ }
Instances For
theorem
Submodule.mem_traceDual
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
{x : L}
:
x ∈ Submodule.traceDual A K I ↔ ∀ a ∈ I, ((Algebra.traceForm K L) x) a ∈ (algebraMap A K).range
theorem
Submodule.le_traceDual_iff_map_le_one
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
{J : Submodule B L}
:
I ≤ Submodule.traceDual A K J ↔ Submodule.map (↑A (Algebra.trace K L)) (Submodule.restrictScalars A (I * J)) ≤ 1
theorem
Submodule.le_traceDual_mul_iff
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
{J : Submodule B L}
{J' : Submodule B L}
:
I ≤ Submodule.traceDual A K (J * J') ↔ I * J ≤ Submodule.traceDual A K J'
theorem
Submodule.le_traceDual
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
{J : Submodule B L}
:
I ≤ Submodule.traceDual A K J ↔ I * J ≤ Submodule.traceDual A K 1
theorem
Submodule.le_traceDual_comm
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
{J : Submodule B L}
:
I ≤ Submodule.traceDual A K J ↔ J ≤ Submodule.traceDual A K I
theorem
Submodule.le_traceDual_traceDual
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
{I : Submodule B L}
:
I ≤ Submodule.traceDual A K (Submodule.traceDual A K I)
theorem
Submodule.traceDual_top'
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
:
Submodule.traceDual A K ⊤ = if Submodule.restrictScalars A (LinearMap.range (Algebra.trace K L)) ≤ 1 then ⊤ else ⊥
theorem
Submodule.traceDual_top
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[Decidable (IsField A)]
:
theorem
Submodule.mem_traceDual_iff_isIntegral
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsFractionRing A K]
[IsIntegrallyClosed A]
{I : Submodule B L}
{x : L}
:
x ∈ Submodule.traceDual A K I ↔ ∀ a ∈ I, IsIntegral A (((Algebra.traceForm K L) x) a)
theorem
Submodule.one_le_traceDual_one
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[FiniteDimensional K L]
[IsIntegrallyClosed A]
:
1 ≤ Submodule.traceDual A K 1
theorem
isIntegral_discr_mul_of_mem_traceDual
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
(I : Submodule B L)
{ι : Type u_4}
[DecidableEq ι]
[Fintype ι]
{b : Basis ι K L}
(hb : ∀ (i : ι), IsIntegral A (b i))
{a : L}
{x : L}
(ha : a ∈ I)
(hx : x ∈ Submodule.traceDual A K I)
:
IsIntegral A (Algebra.discr K ⇑b • a * x)
If b
is an A
-integral basis of L
with discriminant b
, then d • a * x
is integral over
A
for all a ∈ I
and x ∈ Iᵛ
.
theorem
map_equiv_traceDual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsFractionRing B L]
[IsDomain B]
[NoZeroSMulDivisors A B]
(I : Submodule B (FractionRing B))
:
Submodule.map (FractionRing.algEquiv B L) (Submodule.traceDual A (FractionRing A) I) = Submodule.traceDual A K (Submodule.map (FractionRing.algEquiv B L) I)
noncomputable def
FractionalIdeal.dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsDomain B]
[IsIntegrallyClosed A]
(I : FractionalIdeal (nonZeroDivisors B) L)
:
The dual of a non-zero fractional ideal is the dual of the submodule under the traceform.
Equations
- FractionalIdeal.dual A K I = if hI : I = 0 then 0 else ⟨Submodule.traceDual A K ↑I, ⋯⟩
Instances For
theorem
FractionalIdeal.coe_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
:
↑(FractionalIdeal.dual A K I) = Submodule.traceDual A K ↑I
@[simp]
theorem
FractionalIdeal.coe_dual_one
(A : Type u_1)
(K : Type u_2)
(L : Type u)
(B : Type u_3)
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
:
↑(FractionalIdeal.dual A K 1) = Submodule.traceDual A K 1
@[simp]
theorem
FractionalIdeal.dual_zero
(A : Type u_1)
(K : Type u_2)
(L : Type u)
(B : Type u_3)
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
:
FractionalIdeal.dual A K 0 = 0
theorem
FractionalIdeal.mem_dual
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
{x : L}
:
x ∈ FractionalIdeal.dual A K I ↔ ∀ a ∈ I, ((Algebra.traceForm K L) x) a ∈ (algebraMap A K).range
theorem
FractionalIdeal.dual_ne_zero
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
:
FractionalIdeal.dual A K I ≠ 0
@[simp]
theorem
FractionalIdeal.dual_eq_zero_iff
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
:
FractionalIdeal.dual A K I = 0 ↔ I = 0
theorem
FractionalIdeal.dual_ne_zero_iff
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
:
FractionalIdeal.dual A K I ≠ 0 ↔ I ≠ 0
theorem
FractionalIdeal.le_dual_inv_aux
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
{J : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
(hIJ : I * J ≤ 1)
:
J ≤ FractionalIdeal.dual A K I
theorem
FractionalIdeal.one_le_dual_one
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
:
1 ≤ FractionalIdeal.dual A K 1
theorem
FractionalIdeal.le_dual_iff
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
{J : FractionalIdeal (nonZeroDivisors B) L}
(hJ : J ≠ 0)
:
I ≤ FractionalIdeal.dual A K J ↔ I * J ≤ FractionalIdeal.dual A K 1
theorem
FractionalIdeal.inv_le_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
(I : FractionalIdeal (nonZeroDivisors B) L)
:
I⁻¹ ≤ FractionalIdeal.dual A K I
theorem
FractionalIdeal.dual_inv_le
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
(I : FractionalIdeal (nonZeroDivisors B) L)
:
(FractionalIdeal.dual A K I)⁻¹ ≤ I
theorem
FractionalIdeal.dual_eq_mul_inv
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
(I : FractionalIdeal (nonZeroDivisors B) L)
:
FractionalIdeal.dual A K I = FractionalIdeal.dual A K 1 * I⁻¹
theorem
FractionalIdeal.dual_div_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
{J : FractionalIdeal (nonZeroDivisors B) L}
:
FractionalIdeal.dual A K J / FractionalIdeal.dual A K I = I / J
theorem
FractionalIdeal.dual_mul_self
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
:
FractionalIdeal.dual A K I * I = FractionalIdeal.dual A K 1
theorem
FractionalIdeal.self_mul_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
:
I * FractionalIdeal.dual A K I = FractionalIdeal.dual A K 1
theorem
FractionalIdeal.dual_inv
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
:
FractionalIdeal.dual A K I⁻¹ = FractionalIdeal.dual A K 1 * I
@[simp]
theorem
FractionalIdeal.dual_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
(I : FractionalIdeal (nonZeroDivisors B) L)
:
FractionalIdeal.dual A K (FractionalIdeal.dual A K I) = I
@[simp]
theorem
FractionalIdeal.dual_le_dual
(A : Type u_1)
(K : Type u_2)
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
{J : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
(hJ : J ≠ 0)
:
FractionalIdeal.dual A K I ≤ FractionalIdeal.dual A K J ↔ J ≤ I
theorem
FractionalIdeal.dual_involutive
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
:
theorem
FractionalIdeal.dual_injective
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
:
def
differentIdeal
(A : Type u_1)
(B : Type u_3)
[CommRing A]
[CommRing B]
[Algebra A B]
[IsDomain A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
:
Ideal B
The different ideal of an extension of integral domains B/A
is the inverse of the dual of A
as an ideal of B
. See coeIdeal_differentIdeal
and coeSubmodule_differentIdeal
.
Equations
- differentIdeal A B = Submodule.comap (Algebra.linearMap B (FractionRing B)) (1 / Submodule.traceDual A (FractionRing A) 1)
Instances For
theorem
coeSubmodule_differentIdeal_fractionRing
(A : Type u_1)
(B : Type u_3)
[CommRing A]
[CommRing B]
[Algebra A B]
[IsDomain A]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
[Algebra.IsIntegral A B]
[Algebra.IsSeparable (FractionRing A) (FractionRing B)]
[FiniteDimensional (FractionRing A) (FractionRing B)]
:
IsLocalization.coeSubmodule (FractionRing B) (differentIdeal A B) = 1 / Submodule.traceDual A (FractionRing A) 1
theorem
coeSubmodule_differentIdeal
(A : Type u_1)
(K : Type u_2)
{L : Type u}
(B : Type u_3)
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
:
IsLocalization.coeSubmodule L (differentIdeal A B) = 1 / Submodule.traceDual A K 1
theorem
coeIdeal_differentIdeal
(A : Type u_1)
(K : Type u_2)
(L : Type u)
(B : Type u_3)
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
:
↑(differentIdeal A B) = (FractionalIdeal.dual A K 1)⁻¹
theorem
differentialIdeal_le_fractionalIdeal_iff
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : FractionalIdeal (nonZeroDivisors B) L}
(hI : I ≠ 0)
[NoZeroSMulDivisors A B]
:
↑(differentIdeal A B) ≤ I ↔ Submodule.map (↑A (Algebra.trace K L)) (Submodule.restrictScalars A ↑I⁻¹) ≤ 1
theorem
differentialIdeal_le_iff
{A : Type u_1}
{K : Type u_2}
{L : Type u}
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[IsFractionRing B L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
{I : Ideal B}
(hI : I ≠ ⊥)
[NoZeroSMulDivisors A B]
:
differentIdeal A B ≤ I ↔ Submodule.map (↑A (Algebra.trace K L)) (Submodule.restrictScalars A ↑(↑I)⁻¹) ≤ 1
theorem
traceForm_dualSubmodule_adjoin
(A : Type u_1)
(K : Type u_2)
{L : Type u}
[CommRing A]
[Field K]
[Field L]
[Algebra A K]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsDomain A]
[IsFractionRing A K]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
{x : L}
(hx : Algebra.adjoin K {x} = ⊤)
(hAx : IsIntegral A x)
:
(Algebra.traceForm K L).dualSubmodule (Subalgebra.toSubmodule (Algebra.adjoin A {x})) = ((Polynomial.aeval x) (Polynomial.derivative (minpoly K x)))⁻¹ • Subalgebra.toSubmodule (Algebra.adjoin A {x})
theorem
conductor_mul_differentIdeal
(A : Type u_1)
(K : Type u_2)
(L : Type u)
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
(x : B)
(hx : Algebra.adjoin K {(algebraMap B L) x} = ⊤)
:
conductor A x * differentIdeal A B = Ideal.span {(Polynomial.aeval x) (Polynomial.derivative (minpoly A x))}
theorem
aeval_derivative_mem_differentIdeal
(A : Type u_1)
(K : Type u_2)
(L : Type u)
{B : Type u_3}
[CommRing A]
[Field K]
[CommRing B]
[Field L]
[Algebra A K]
[Algebra B L]
[Algebra A B]
[Algebra K L]
[Algebra A L]
[IsScalarTower A K L]
[IsScalarTower A B L]
[IsDomain A]
[IsFractionRing A K]
[IsIntegralClosure B A L]
[FiniteDimensional K L]
[Algebra.IsSeparable K L]
[IsIntegrallyClosed A]
[IsDedekindDomain B]
[NoZeroSMulDivisors A B]
(x : B)
(hx : Algebra.adjoin K {(algebraMap B L) x} = ⊤)
:
(Polynomial.aeval x) (Polynomial.derivative (minpoly A x)) ∈ differentIdeal A B